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Šwp˜_•¶E’˜‘

2021”N

1. Tani, Y., Kakinuma, S., Chang, J., Tanaka, K., Miyata, N.: Preferential elimination of Ba2+ through irreversible biogenic manganese oxide sequestration. Minerals, 2021, 11(1), 53, DOI:10.3390/min11010053 @https://www.mdpi.com/2075-163X/11/1/53
2. Sugawara, K., Fujibayashi, M., Okano, K., Enda, Y., Ichinoseki, S., Taniguchi, Y., Miyata, N.: Assimilation of cyanobacteria by the freshwater bivalve Nodularia douglasiae: insights from long-term laboratory and field feeding experiments, Journal of Water and Environmental Technology, 2021, in press.


2020”N

1. Suzuki, R., Tani, Y., Naitou, H., Miyata, N., Tanaka, K.: Sequestration and oxidation of Cr(III) by fungal Mn oxides with Mn(II) oxidizing activity. Catalysts, 2020, 10, 44; DOI: 10.3390/catal10010044.
https://doi.org/10.3390/catal10010044
2. Okano, K., Shimizu, K., Saito, T., Maseda, H., Utsumi, M., Itayama, T., Sugiura, N.: Draft Genome Sequence of the Microcystin-Degrading Bacterium Novosphingobium sp. Strain MD-1, https://mra.asm.org/content/9/12/e01413-19
3. Tojo, F., Kitayama, A., Miyata, N., Okano, K., Fukushima, J., Suzuki, R., Tani, Y.: Molecular cloning and heterologous expression of manganese(II)-oxidizing enzyme from Acremonium strictum strain KR21-2, Catalysts, 2020, 10(6), 686; DOI: 10.3390/catal10060686.
https://doi.org/10.3390/catal10060686
4. Fujibayashi, M., Takakai, F., Masuda, S., Okano, K., Miyata, N.: Effects of restoration of emergent macrophytes on the benthic environment of the littoral zone of a eutrophic lake, Ecological Engineering, 2020, 155, 105960; DOI: 10.1016/j.ecoleng.2020.105960.
https://www.sciencedirect.com/science/article/pii/S0925857420302482
5. Furuta, S., Ishikawa, K., Miyata, N.: 3.3.2 Recent changes in the profundal benthic microbes. In Lake Biwa: Interactions between Nature and People, 2nd ed (Kawanabe, H., Nishino, M., Maehata, M.), pp 361-364, Springer (2020). y’˜‘z
6. ‹{“c’¼KC’JK‘¥F”÷¶•¨‚É‚æ‚éƒ}ƒ“ƒKƒ“Ž_‰»•¨‚̐¶¬ -”÷¶•¨\‹à‘®‘ŠŒÝì—p‚Ɗ‹«‹Zp‚ւ̉ž—pD‰»Šw‚Ɛ¶•¨Cvol. 58, 10, 562-570 (2020). y‰ðàz
7. V“c^‹|C“¡—ÑŒbCÂX‘s‘¿C‰ª–ì–MGC‹{“c’¼KF”ª˜YŒÎ‚É‚¨‚¯‚郏ƒJƒTƒM‚̃]ƒEƒ~ƒWƒ“ƒR‚ɑ΂·‚é•ßH‚Ì—L–³‚Æ‘I‘𐫂̕]‰¿C“y–ØŠw‰ï˜_•¶WGiŠÂ‹«j, 76, 7, III_1-9 (2020).
8. Watanabe, M., Kojima, H., Fukui, M.: Labilibaculum antarcticum sp. nov., a novel facultative anaerobic, psychrotorelant bacterium isolated from marine sediment of Antarctica, Antonie van Leeuwenhoek, 113(3), 349-355, 2020.
https://link.springer.com/article/10.1007/s10482-019-01345-w
9. Watanabe, M., Kojima, H., Fukui, M.: Aerosticca soli gen. nov., sp. nov., an aerobic gammaproteobacterium isolated from crude oil-contaminated soil, Archives of Microbiology, 202(5), 1069-1076, 2020.
https://doi.org/10.1007/s00203-020-01819-w
10. Watanabe, M., Higashioka, Y., Kojima, H., Fukui, M.: Proposal of Desulfosarcina ovata subsp. sediminis subsp. nov., a novel toluene-degrading sulfate-reducing bacterium isolated from tidal flat sediment of Tokyo Bay, Systematic and Applied Microbiology, 43(5), 126109-126109, 2020.
https://www.sciencedirect.com/science/article/pii/S0723202020300643
11. Watanabe, M., Kojima, H., Fukui, M.: Aquipluma nitroreducens gen. nov. sp. nov., a novel facultatively anaerobic bacterium isolated from a freshwater lake. International Journal of Systematic and Evolutionary Microbiology, 70(12), 6408-6413, 2020.
https://www.microbiologyresearch.org/content/journal/ijsem/10.1099/ijsem.0.004551
12. Watanabe, M., Fukui, M., Galushko, A., Kuver, J.: Bergey's manual of Systematics of Archaea and Bacteria, 2020.3.y’˜‘z
Desulfolucanica gen. nov. -Wiley Online Library
Desulfocucumaceae fam. nov. - Wiley Online Library
Desulfoplanes -Wiley Online Library
Desulfocucumis - Wiley Online Library
Desulfotruncus gen. nov. - Wiley Online Library
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2019”N

1. ›Œ´I‘¾˜NA“¡—ÑŒbA‰““cK¶Ar–Ø”ü•äA‰ª–ì–MGA‹{“c’¼KF•x‰h—{‰»ŒÎÀ‚̐󂢉ˆŠÝˆæ‚É‚¨‚¯‚é—•‘”—Þ‚Ì“úŽü‰”’¼ˆÚ“®‚Ɖh—{‰–“®‘Ô‚ÌŠÖŒWC“ú–{…ˆ—¶•¨Šw‰ïŽCVol. 55Cpp. 49-57 (2019)
2. Xu, X., Li, W., Den, H., Fujibayashi, M., Nomura, M., Nishimura, O., Wang, G.: Approach deliberation for source identification of sedimentary organic matters via comparing freshwater lakes with multi-ecotypes. Science of the Total Environment, Vol. 649, 327-334 (2019)
3. Fujibayashi, M., Sakamaki, T., Nishimura, O.: Effect of sedimentary organic matter on species richness of deposit feeders in enclosed bay ecosystems: Insight from fatty acid nutritional indicators, Marine Environmental Research, Vol. 149, 1-6 (2019)
4. Fujibayashi, M., Ashino, M., Okano, K., Miyata, N.: Spatial and seasonal variability of sedimentary organic matter and its origin in an algal-blooming eutrophic lake. Ecological Indicator, 107, DOI: 10.1016/j.ecolind.2019.105557
5. Fukasawa, Y., Ando, Y., Oishi, Y., Matsukura, K., Okano, K., Song, Z., Sakuma, D.: Effects of forest dieback on wood decay, saproxylic communities, and spruce seedling regeneration on coarse woody debris. Fungal Ecology, 41, 198-208 (2019).
6. Fukasawa, Y., Ando, Y., Oishi, Y., Suzuki, S.N., Matsukura, K., Okano, K., Song, Z. Does typhoon disturbance in subalpine forest have long-lasting impacts on saproxylic fungi, bryophytes, and seedling regeneration on coarse woody debris? Forest Ecology and Management, 432, pp. 309-318 (2019).
7. Hao, L., Okano, K., Zhang, C., Zhang, Z., Lei, Z., Feng, C., Utsumi, M., Ihara, I., Maseda, H., Shimizu, K. Effects of levofloxacin exposure on sequencing batch reactor (SBR) behavior and microbial community changes. Science of the Total Environment, 672, pp. 227-238 (2019).
8. Fujibayashi, M., Miura, Y., Suganuma, R., Takahashi, S., Sakamaki, T., Miyata, N., Kazama, S.: Origin of carbon and essential fatty acids in higher trophic level fish in headwater stream food webs. Biomolecules, 9, 487, doi:10.3390/ biom9090487 (2019).
9. “¡—ÑŒbC’¿“c®rC‹{“c’¼KF”ª˜YŒÎ‚ɐ¶‘§‚·‚éƒVƒWƒ~—ނ̏H‹G‚É‚¨‚¯‚é‚ë‰ß‘¬“x‚ÆŽ_‘fÁ”“xC“ú–{…ˆ—¶•¨Šw‰ïŽC55(3), 59-65 (2019).
10. ‹g“c‹œC“¡—ÑŒbC“c’†mŽuC‰ª–ì–MGC‚“c–F”ŽC‹{“c’¼KF•x‰h—{ŒÎÀ‚É‚¨‚¯‚éŽá”NŒÂ‘Ì‚ª­‚È‚¢ƒCƒVƒKƒCŒÂ‘ÌŒQ‚̍жŽYó‹µC“y–ØŠw‰ï˜_•¶W‚fiŠÂ‹«), 75, 7, III 264-273 (2019).
11. ÂX‘s‘¾C“¡—ÑŒbC‰ª–ì–MGC‚“c–F”ŽC‹{“c’¼KFŽ‰–bŽ_‘g¬‚ðŽw•W‚Æ‚µ‚½¬Œ^bŠk—ނ̃AƒIƒRŒ`¬—•‘”—ނɑ΂·‚é‰a—˜—p“Á«C“y–ØŠw‰ï˜_•¶W‚fiŠÂ‹«), 75, 7, III 367-374 (2019)
12. ’JK‘¥C‹{“c’¼KFMn(II)y‘fŠˆ«ƒoƒCƒIƒ}ƒ“ƒKƒ“Ž_‰»•¨‚É‚æ‚郌ƒAƒƒ^ƒ‹‰ñŽûCŠÂ‹«‹ZpC48, 6, 314-317 (2019) [‰ðà˜_•¶]


2018”N

 1 Xia, D., Okano, K., Miura, Y., Okada, K., Watanabe, K., Ramaraj, R., Itayama, T.: The effect of magnesium hydroxide for the microbial community in the sediments of a eutrophic closed bay. International Journal of GEOMATE, 14(41) 143-150 (2018)
 2 Araki, M., Okano, K., Ohta, S., Suzuki, E., Fujibayashi, M., Miyata, N.: Characteristics of harmful algal blooms during a low water temperature season in Lake Hachiro. Journal of Water and Environment Technology, 16(4), 175-183 (2018) 
 3 Miyata, N., Takahashi, A., Fujii, T., Hashimoto, H., Takada, J.: Biosynthesis of schwertmannite and goethite in a bioreactor with acidophilic Fe(II)-oxidizing betaproteobacterium strain GJ-E10. Minerals, 8, 98, (2018) doi: 10.3390/min8030098
 4 r–Ø”ü•äA‰ª–ì–MGA“¡—ÑŒbA‹{“c’¼KFH“cŒ§”ª˜YŒÎ‚ō̎悵‚½’ꎿ‚©‚ç‚Ì—•‘”‰ñ‹A‚É‹y‚Ú‚·’ቷˆ—‚Æ”|—{‰·“x‚̉e‹¿A“ú–{…ˆ—¶•¨Šw‰ïŽA54App.55-63@i2018j
 5 Fujibayashi, M., Tanaka, N., Hashido, S., Takasawa, A., Nishimura, O.: Nutritional quality of fish faeces is enhanced by highly unsaturated fatty acid-producing heterotrophic protozoa. Acta Oecologia, 89, pp21-26 (2018) 
 6 Fujibayashi, M., Okano, K., Takada, Y., Mizutani, H., Uchida, N., Nishimura, O., Miyata, N.: Transfer of cyanobacterial carbon to a higher trophic-level fish community in a eutrophic lake food web: fatty acid and stable isotope analyses. Oecologia, 188, pp. 901-912 (2018)
ì”¨’B–îA“¡—ÑŒbA“’ã—m•½A¼‘ºCAâŠª—²ŽjFŠC…’†—±ó—L‹@•¨‚̉»Šw‘g¬‚ÆŽ_‘fÁ”ï‚É‹y‚Ú‚·ƒJƒL—{Bê‚̉e‹¿A“y–ØŠw‰ï˜_•¶WGAVol. 74Ap. III_63-III_71 (2018)
 8 ‘匴ŒõŽiA“’ã—m•½Aì”¨’B–îA“¡—ÑŒbA¼‘ºCAâŠª—²ŽjFŽ‰–bŽ_‘g¬•ªÍ‚ð—˜—p‚µ‚½“à˜pˆêŽŸ¶ŽY‚̐§ŒÀˆöŽq‚Ì•]‰¿A“y–ØŠw‰ï˜_•¶WGAVol. 74Ap. III_53-III_61 (2018) 


2017”N

1 Zheng, H., Tani, Y., Naitou, H., Miyata, N., Tojo, F., and Seyama, H.:Sequestration of La3+ by fungal manganese oxides and the effect of Mn(II) oxidase activity, Journal of Environmental Chemical Engineering, 5, 735-743 (2017). i^‹Û‚ªŒ`¬‚·‚éƒ}ƒ“ƒKƒ“Ž_‰»•¨‚ƃ‰ƒ“ƒ^ƒ“‚Ì”½‰žj
2 Leon-Romero, M. A., Soto-Rios, P. C., Fujibayashi, M. and Nishimura, O.: Impact of NaCl solution pretreatment on plant growth and the uptake of multi-heavy metal by the model plant Arabidopsis thaliana, Water Air and Soil Pollution, 228 (2017).iƒVƒƒCƒkƒiƒYƒi‚̐¬’·‚Æ•¡”‚̏d‹à‘®‹zŽû‚ɉ–‰»ƒiƒgƒŠƒEƒ€—n‰t‚É‚æ‚é‘Oˆ—‚ª—^‚¦‚é‰e‹¿j
Saito, R., Kaiho, K., Oba, M., Tong, J., Chen, Z-Q., Tian, L., Takahashi, S., Fujibayashi, M.: Tentative identification of diagenetic products of cyclic biphytanes in sedimentary rocks from the uppermost Permian and Lower Triassic, Organic Geochemistry, 111, pp. 144-153, 2017.
Itoh, M., Kojima, H., Ho, P. C., Chang, C. W., Chen, T. Y., Hsiao, S. S. Y., Kobayashi, Y., Fujibayashi, M., Kao, S. J., Hsieh, C., Fukui, M., Okuda, N., Shiah, F. K., Miki, T.: Integrating isotopic, microbial, and modeling approaches to understand methane dynamics in a frequently disturbed deep reservoir in Taiwan, Ecological Research, 32, pp.861-871, 2017
5 –쑺 @OCç—t ‚”VC“¡—Ñ ŒbC¼‘º CFƒnƒX‚Ì’·Šú•ª‰ðŽÀŒ±‚É‚æ‚é—±ó—L‹@•¨‚ÌŽc‘¶Š„‡‚Ì•]‰¿‹y‚ђꎿ‚ւ̑͐όXŒüC“y–ØŠw‰ï˜_•¶WGA73, pp.III_241-III_246, 2017.

2016”N

1 ”öú±•Û•vC‰Á“¡—C—Ñ‹I’jC‘º’†FŽiC‰ª–ì–MGC‹{“c’¼KF”ª˜YŒÎ‚É‚¨‚¯‚é’¾…A•¨‚̍ж‚É—^‚¦‚éŠÂ‹«—vˆö‚̉e‹¿CH“cŒ§—§‘åŠwƒEƒFƒuƒWƒƒ[ƒiƒ‹Ai’nˆævŒ£•”–åjC3C86-92i2016j
2 Fujibayashi, M., Tanaka, H., Nishimura, O.: Evaluation of food sources assimilated by unionid mussels using fatty acid trophic markers in Japanese freshwater ecosystems. Journal of Shellfish Research, 35, 251-255 (2016).iŽ‰–bŽ_ƒoƒCƒIƒ}[ƒJ[‚ð—p‚¢‚½‘“à‚Ì’W…¶‘ÔŒn‚ɐ¶‘§‚·‚éƒCƒVƒKƒC‰È“ñ–‡ŠL‚Ì“¯‰»‰aŒ¹‚ÌŒŸ“¢j 
Fujibayashi, M., Sakamaki, T.,  Shin, W., Nishimura, O.: Food utilization of shell-attached algae contributes to the growth of host mud snail, Bellamya chinensis: Evidence from fatty acid biomarkers and carbon stable isotope analysis. Limnologica, 57, 66-72 (2016).iƒ}ƒ‹ƒ^ƒjƒV‚É‚æ‚éŠkã‚Ì•t’…«‘”—ނ̉a—˜—p‚ª¬’·‚𑣐i‚·‚éFŽ‰–bŽ_ƒoƒCƒIƒ}[ƒJ[‚Æ’Y‘fˆÀ’蓯ˆÊ‘Ì”ä‚̉ðÍ‚©‚çj 
4 Fujibayashi, M., Ogino, M., Nishimura, O.: Fractionation of stable carbon isotope ratio of essential fatty acids in zebrafish Danio rerio and mud snails Bellamya chinensis. Oecologia, 180, 589-600 (2016).iƒ}ƒ‹ƒ^ƒjƒV‚ƃ[ƒuƒ‰ƒtƒBƒbƒVƒ…‚É‚¨‚¯‚é•K{Ž‰–bŽ_‚Ì’Y‘fˆÀ’蓯ˆÊ‘Ì”ä‚Ì”ZkŒW”j
Shimizu, K., Utsumi, M., Okano, K., Itayama, T., Iwami, N., Maseda, H., Kinohira, H., Li, J., Inamori, Y., Zhang, Z., Sugiura, N.: Removal of Microcystis aeruginosa cells and microcystin-LR using ceramic carrier in a continuous flow bioreactor. Japanese Journal of Water Treatment Biology, 52(2), 35-43 (2016).
 6  Zheng, H., Tani, Y., Naitou, H., Miyata, N., and Tojo, F.: Oxidative Ce3+ sequestration by fungal manganese oxides with an associated Mn(II) oxidase activity. Applied Geochemistry, 71, 110-122 (2016).i^‹Û‚ªŒ`¬‚·‚éƒ}ƒ“ƒKƒ“Ž_‰»•¨‚É‚æ‚éƒZƒŠƒEƒ€‚ÌŽ_‰»”½‰žj
 7  Okano, K., Furuta, S., Ichise, S., and Miyata, N.: Whole genome sequences of two manganese(II)-oxidizing bacteria, Bosea sp. strain BIWAKO-01 and Alphaproteobacterium strain U9-1i, Genome Announcements, 4 (6), e01309-16 (2016). iƒ}ƒ“ƒKƒ“Ž_‰»×‹Û‚̃Qƒmƒ€”z—ñj
 8  ‹{“c’¼KF”pŠü•¨‚©‚ç‚Ì‹à‘®‰ñŽûEÄŽ‘Œ¹‰»‚Ì‚½‚߂̃oƒCƒIƒŠ[ƒ`ƒ“ƒO‹ZpCƒNƒŠ[ƒ“ƒeƒNƒmƒƒW[C26(5), 47-50 (2016).
 9  ¬“cCŽiC‹{“c’¼KF“c‘òŒÎ—¬ˆæ‚̐…ŠÂ‹«‚Ɛ…Ž¿‰ü‘PC“ú–{…ŠÂ‹«Šw‰ïŽC39(A), 7, 242-245 (2016).
 10 Kaiho, K., Oshima, N., Adachi, K., Adachi, Y., Mizukami, T., Fujibayashi, M. and Saito, R.: Global climate change driven by soot at the K-Pg boundary as the cause of the mass extinction. Scientific Reports, 6, 28427 (2016). iK-Pg‹«ŠE‚Ő¶¬‚µ‚½‚·‚·‚É‚æ‚Á‚悶‚½‘S‹…‹K–Í‚Ì‹CŒó•Ï“®‚ª‘å—ʐâ–Å‚ðˆø‚«‹N‚±‚µ‚½j
 11 Li, W., Xu, X., Fujibayashi, M., Tanaka, N., Nishimura, O.: Response of microalgae to elevated CO2 and temperature: impact of climate change on freshwater ecosystems, Environmental Science and Pollution Research, 23, pp. 19847-19860 (2016). (“ñŽ_‰»’Y‘f‚Ɖ·“xã¸‚ɑ΂·‚é”÷×‘”—ނ̃ŒƒXƒ|ƒ“ƒXF‹CŒó•Ï“®‚ª’W…¶‘ÔŒn‚É—^‚¦‚é‰e‹¿)
 12 Ho, P-C., Okuda, N., Miki, T., Itoh, M., Shiah, F-K., Chang, C-W., Hsiao, S. S-Y., Kao, S-J., Fujibayashi, M., and Hsieh, C-H.: Summer profundal hypoxia rather than winter mixing determines the coupling of methanotrophic production and pelagic food web. Freshwater Biology, 61, pp. 1694-1706 (2016). i“~‹G‚̏zŠÂ‚Å‚Í‚È‚­‰Ä‹G‚Ì’áŽ_‘f‚ªƒƒ^ƒ“‰h—{‚̐¶ŽY‚ƐH•¨–Ô‚ðŒˆ’è‚·‚éj
 13  “¡—ÑŒbA‹´ŒËxA“c’†LKA–쑺@OA¼‘ºCFŒ´¶“®•¨Cyclidium‚¨‚æ‚ÑGlaucoma‚É‚æ‚é•K{Ž‰–bŽ_‚̍‡¬A“y–ØŠw‰ï˜_•¶WGAVol. 72A pp.‡V_567-‡V_572 (2016).

2015”N

1 ‰ª–ì–MGC—é–؉pŽ¡C‘¾“cžxC‹{“c’¼KC’JK‘¥C”öú±•Û•vFH“cŒ§”ª˜YŒÎ‚É‚¨‚¯‚é—•‘”“Ń~ƒNƒƒVƒXƒ`ƒ“‚Æ—L“Å—•‘”‚Ì‹Gß“I•Ï“®, “ú–{…ŠÂ‹«Šw‰ïŽ, 38, 23-30 (2015)
2 ”öú±•Û•vC´…ìˆ®C‰ª–ì–MGC²“¡FC‹{“c’¼KFƒZƒXƒoƒjƒAAÍBGF…˜H‚É‚æ‚邵”Aˆ—…‚Ì’‚‘fCƒŠƒ“œ‹ŽC—p…‚Æ”p…, 57 (3), 202-210 (2015).
3 Fukushima, J., Tojo, F., Asano, R., Kobayashi, Y., Shimura, Y., Okano, K., Miyata, N.: Complete genome sequence of the unclassified iron-oxidizing, chemolithoautotrophic Burkholderiales bacterium GJ-E10 isolated from an acidic river. Genome Announcements, 3 (1), e01455-14 (2015).
iV‹KDŽ_«“SŽ_‰»×‹ÛGJ-E10Š”‚Ì‘SƒQƒmƒ€”z—ñŒˆ’èj
4 Furuta, S., Ikegaya, H., Hashimoto, H., Ichise, S., Kohno, T., Miyata, N., and Takada, J.: Formation of filamentous Mn oxide particles by the alphaproteobacterium Bosea sp. strain BIWAKO-01. Geomicrobiology Journal, 32, 666-676 (2015). i”ú”iŒÎ’ê‘w•”‚Ő¶¬‚·‚éƒ}ƒ“ƒKƒ“Ž_‰»•¨—±Žq‡€ƒƒ^ƒƒQƒjƒEƒ€—±Žqh‚̐¶¬‹@\|ƒƒ^ƒƒQƒjƒEƒ€—±Žq¶¬‹Û‚Ì”|—{ŒnŠm—§‚Æ‘B“Á«‚ɂ‚¢‚āj
Okano, K., Miyata, N., Ozaki, Y.: Draft genome sequence of the non-toxic bloom-forming cyanobacterium Microcystis aeruginosa NIES-44. Genome Announcements, in press (2015).
iƒAƒIƒRŒ`¬—•‘”i–³“ÅŠ”j‚Ì‘SƒQƒmƒ€”z—ñŒˆ’èj
y’˜‘z‹{“c’¼KC“ŒžŠ‚Ó‚ä‚݁C’JK‘¥FDŽ_«“SŽ_‰»‹Û‚ð—˜—p‚µ‚½”p“dŽqŠî”“™‚̃oƒCƒIƒŠ[ƒ`ƒ“ƒOCuƒoƒCƒIƒx[ƒXŽ‘Œ¹Šm•Ûí—ªi¬¼N—TŠÄCjCƒV[ƒGƒ€ƒV[o”ŁCp 1-8C2015.7. 
7 y’˜‘z’JK‘¥Cí‰À”JD‹{“c’¼KFƒoƒCƒIƒ}ƒ“ƒKƒ“Ž_‰»•¨‚É‚æ‚é”p…“™‚©‚ç‚̃ŒƒAƒƒ^ƒ‹‰ñŽûCuƒoƒCƒIƒx[ƒXŽ‘Œ¹Šm•Ûí—ªi¬¼N—TŠÄCjCƒV[ƒGƒ€ƒV[o”ŁCp 74-81C2015.7.


2014”N

1 ”öú±•Û•vF”ª˜YŒÎ‚̐…ŠÂ‹«‰ü‘P‚ð‚ß‚´‚µ‚½’¾…A•¨‚̍ж‚ƉۑèC”ª˜YŒÎ—¬ˆæŠÇ—Œ¤‹†C‘æ‚R†C27-36 (2014.3.)
2 ”öú±•Û•vFˆù—¿…‰˜õ, p 245; ‰˜“D, p.259; …“c‚̏ò‰»”\, p 353; “y‚Ì•S‰ÈŽ–“T•ÒWˆÏˆõ‰ï•Ò,@“y‚Ì•S‰ÈŽ–“TCŠÛ‘Po”Å (2014.1) 
3 Iwahori, K., Watanabe, J., Tani, Y., Seyama, H., and Miyata, N.: Removal of heavy metal cations by biogenic magnetite nanoparticles produced in Fe(III)-reducing microbial enrichment cultures. Journal of Bioscience and Bioengineering, 117 (3), 333-335 (2014).iƒoƒCƒIƒ}ƒOƒlƒ^ƒCƒg‚É‚æ‚éd‹à‘®ƒCƒIƒ“‚Ì‹z’…œ‹Žj
4 Inthorn, D., Tani, Y., Chang, J., Naitou, H., and Miyata, N.: Magnetically modified fungal Mn oxides with high sequestration efficiency for simultaneously removing multiple heavy metal ions from wastewater. Journal of Environmental Chemical Engineering, 2 (3), 1635-1641 (2014). (ƒoƒCƒI‚l‚ŽŽ_‰»•¨/ƒ}ƒOƒlƒ^ƒCƒg‚ð—p‚¢‚½”p…‚©‚ç‚̏d‹à‘®œ‹Žj
5 Chang, J., Tani, Y., Naitou, H., Miyata, N., Tojo, F., and Seyama, H.: Zn(II) sequestration by fungal biogenic manganese oxide through enzymatic and abiotic processes. Chemical Geology, 383, 155-163 (2014).iy‘f‚ð•ÛŽ‚µ‚½ƒoƒCƒI‚l‚ŽŽ_‰»•¨‚É‚æ‚鈟‰”‚Ì‹z’…j
6 Chang, J., Tani, Y., Naitou, H., Miyata, N., and Seyama, H.: Sequestration of Cd(II) and Ni(II) ions on fungal manganese oxides associated with Mn(II) oxidase activity. Applied Geochemistry, 47, 198-208 (2014).iy‘f‚ð•ÛŽ‚µ‚½ƒoƒCƒI‚l‚ŽŽ_‰»•¨‚É‚æ‚éƒJƒhƒ~ƒEƒ€AƒjƒbƒPƒ‹‚Ì‹z’…j
7 ƒ‰ðà„@’JK‘¥Cí‰À”JC“n糏~ˆêC‹{“c’¼KFuƒoƒCƒI‡¬ƒ}ƒ“ƒKƒ“Ž_‰»•¨‚É‚æ‚é”÷—ÊŒ³‘f‚̏ˆ—‚ƉñŽûvC—p…‚Æ”p…C56 (1): 32-40 (2014)
8 ƒ‰ðà„@’JK‘¥Cí‰À”JC‹{“c’¼KFu”÷¶•¨‚É‚æ‚éƒ}ƒ“ƒKƒ“Ž_‰»•¨‚ÌŒ`¬‚ð—˜—p‚µ‚½ƒŒƒAƒƒ^ƒ‹‚̉ñŽû–@vCBIO INDUSTRYC31 (2): 34-40 (2014).


2013”N

1 ”öú±•Û•vC‰ª–ì–MGC‚“c‡C—Ñ‹I’jF”ª˜YŒÎ‚̐…Ž¿‰ü‘P‚ð–ÚŽw‚µ‚½–„“yŽíŽq“™‚ð—p‚¢‚½’¾…A•¨‚̍ж‚ƉۑèC—p…‚Æ”p…, 55 (6), 459-467 (2013).
2 ”öú±•Û•vC‹gìi‘¾˜YCŠÚ“cçtC—Ñ‹I’jF–„“yŽíŽq‚ð—p‚¢‚½’¾…A•¨Ä¶‚É‹y‚Ú‚·‘÷“x‚ÆŒõ—ÊŽq‚̉e‹¿CH“cŽ©‘RŽjŒ¤‹†C63, 1-6 (2013).
3 Watanabe, J., Tani, Y., Chang, J., Naitoh, H., Miyata, N., and Seyama, H.: As(III) oxidation kinetics of biogenic manganese oxides formed by Acremonium strictum strain KR21-2. Chemical Geology, 347, 227-232 (2013).iƒoƒCƒIƒ}ƒ“ƒKƒ“Ž_‰»•¨‚É‚æ‚éƒq‘f‚ÌŽ_‰»‚ɂ‚¢‚āj
4 –Ø‘º—ύNC‹´–{‰pŽ÷C‹{“c’¼KCm‰È—E‘¾C‘–ìŒ\OC’r“c–õŒPC’†¼^C“¡ˆä’B¶CIvo SafarikCMirka SafarikovaC‚“c F”÷¶•¨‚ªì‚éƒ}ƒ“ƒKƒ“Ž_‰»•¨‚̉Á”Mˆ—‚É‚æ‚錋»\‘¢‚Æ”÷×\‘¢‚̕ω»D•´‘Ì‚¨‚æ‚Ñ•²–––è‹àC60 (3): 92-99 (2013)
5 ƒ’˜‘„@’JK‘¥C‹{“c’¼KCí‰À”JFuMnŽ_‰»•¨Œ`¬”\‚ð—L‚·‚é”÷¶•¨‚É‚æ‚郌ƒAƒƒ^ƒ‹‚̉ñŽûvCƒŠƒTƒCƒNƒ‹ƒoƒCƒIƒeƒNƒmƒƒW[‚̍őOüiA“c[”üŠÄCjCp 170-178CƒV[ƒGƒ€ƒV\o”ŁC2013”N5ŒŽ.@
6 Chang, J., Tani, Y., Naitoh, H., Miyata, N., and Seyama, H.: Fungal Mn oxides supporting Mn(II) oxidase activity as effective Mn(II)@sequestering materials. Environmental Technology, 34 (19), 2785-2791 (2013).
7 Chang, J., Tani, Y., Naitou, H., Miyata, N., Seyama, H., and Tanaka, K.: Cobalt(II) sequestration on fungal biogenic manganese oxide enhanced by manganese(II) oxidase activity. Applied Geochemistry, 37, 170-178 (2013) 
8 ”öú±•Û•vF”_k’n‚É‚¨‚¯‚鉺…‰˜“DƒRƒ“ƒ|ƒXƒg‚̏zŠÂ—˜—p‚ƉۑèAÄ¶‚Æ—˜—pA37(140)A13-15 (2013)
‚“c‡A‰ª–ì–MGA”öè•Û•vFH“cŒ§‘劃‘ºŽYƒCƒgƒNƒYƒ‚Zannnichellia palustris L.‚̐¶‘ԂƐ¶ŠˆŽjA…‘Œ¤‹†‰ïŽA 99†A1-14 (2013) 
10  ”öè•Û•vAŠÚ“cçtA‰ª–ì–MGA—Ñ‹I’jAX“cO•FA‚“c‡F”ª˜YŒÎiH“cŒ§j—¬ˆæ‚É‚¨‚¯‚é“yëƒV[ƒhƒoƒ“ƒN‚Ì’²¸‚Æ’¾…A•¨‚̐öÝ“I”­‰è”\A…‘Œ¤‹†‰ïŽA 99†A31-37 (2013) 

2012”N

1. Nishina, Y., Hashimoto, H., Kimura, N., Miyata, N., Fujii, T., Ohtani, B., and Takada, J.: Biogenic manganese oxide: effective new catalyst for direct bromination of hydrocarbons. RSC Advances, 2 (16), 6420-6423 (2012). (ƒoƒCƒIƒ}ƒ“ƒKƒ“Ž_‰»•¨‚̐G”}—˜—pj

2. Shimizu, K., Maseda, H., Okano, K., Kurashima, T., Kawauchi, Y., Xue, Q., Utsumi, M., Zhang, Z., Sugiura, N.: Enzymatic pathway for biodegrading microcystin LR in Sphingopyxis sp. C-1. Journal of Bioscience and Bioengineering, in press (2012). (×‹Û‚É‚æ‚éƒAƒIƒR“Ń~ƒNƒƒLƒXƒ`ƒ“‚̍y‘f•ª‰ðŒo˜H‚ɂ‚¢‚āj

3. Watanabe, J., Tani, Y., Miyata, N., Seyama, Mitsunobu, S., Naitou, H.: Concurrent sorption of As(V) and Mn(II) during biogenic manganese oxide formation. Chemical Geology,306-307, 123-128 (2012).iƒoƒCƒIƒ}ƒ“ƒKƒ“Ž_‰»•¨‚É‚æ‚éƒq‘f‚Ì‹z’…‚ɂ‚¢‚āj

2011”N

1. Nakamoto, T., Okano, K., Kaul, C.S., and Utsumi, M.: Phylogenetic analysis of microcystin biosynthesis gene-mcyF from Microcystis, Japanese Journal of Water Treatment Biology, 47 (1), 29-36 (2011).iƒAƒIƒR“Ń~ƒNƒƒLƒXƒ`ƒ“‚̐¶‡¬ˆâ“`Žq‚̉ðÍ)

2. Shimizu, K., Maseda, H., Okano, K., Itayama, T., Kawauchi, Y., Chen, R., Utsumi, M., Zhang, Z., and Sugiura, N.FHow microcystin-degrading bacteria express microcystin degradation activity. Lakes & Reservoirs: Research & Management, 16(3), 169-178 (2011)iƒAƒIƒR“Ń~ƒNƒƒLƒXƒ`ƒ“‚Ì”÷¶•¨•ª‰ð‚ɂ‚¢‚āj

3. ”öú±•Û•vF‘æ1Í1.ƒoƒCƒIƒWƒIƒtƒBƒ‹ƒ^[‚É‚æ‚鐶Šˆ”r…‚̍‚“xˆ—CA•¨‹@”\‚̃|ƒeƒ“ƒVƒƒƒ‹‚ðŠˆ‚©‚µ‚½ŠÂ‹«•Û‘SEò‰»‹Zp|’n‹…‚ð‹~‚¤’´ŠÂ‹«“K‡EŽ©‘R’²˜aŒ^ƒVƒXƒeƒ€Cpp 1-9, ƒV[ƒGƒ€ƒV\o”ŁC2011.10.i’˜‘j

4. —Ñ‹I’jC”öú±•Û•vCŽðˆä•s“ñ•FF…¶A•¨AÍò‰»Ž{Ý‚É‚¨‚¯‚鐅¶“®•¨‚̏ò‰»‚ɉʂ½‚·–ðŠ„C“ú–{…ˆ—¶•¨Šw‰ïŽC47(3): 119-129 (2011).

5. Miyata, N., Tani, Y.: Chapter 1. Microbial manganese(II) oxidation: a potential tool for treatment of metal-contaminated waters, In Handbook of Metal Biotechnology: Applications for Environmental Conservation and Sustainability, pp 1-10, Pan Stanford Publishing, 2011.11.iƒ}ƒ“ƒKƒ“Ž_‰»‹Û‚Ì‹à‘®ŠÜ—L”r…ˆ—‚ւ̉ž—p‚ɂ‚¢‚āji’˜‘j

6. ”öú±•Û•vF‘æ2ÍE7 —L—pA•¨‚ð—p‚¢‚½¶Šˆ”r…‚̍‚“xˆ—\àhÞ‚ƐA•¨‚Ì‘g‚ݍ‡‚킹‚ªˆ—…Ž¿‚É‹y‚Ú‚·‰e‹¿C …ò‰»‹Zp‚̍ŐV“®ŒüCpp 151-163, ƒV[ƒGƒ€ƒV\o”ŁC2011.6.i’˜‘j

7. Sawayama, M., Suzuki, T., Hashimoto, H., Kasai, T., Furutani, M., Miyata, N., Kunoh, H., and Takada, J.: Isolation of a Leptothrix strain, OUMS1, from ocherous deposits in groundwater. Current Microbiology, 63: 173-180 (2011).i“SŽ_‰»×‹ÛLeptothrix‚Ì•ª—£‚Æ“Á’¥•t‚¯j

2010”N

1. Abe, K., Kato, K., Ozaki, Y.: Vegetation-based wastewater treatment technologies for rural areas in Japan, JARQ, 44(3)F231-242 (2010).iAÍ‚ð—˜—p‚µ‚½”_‘º’nˆæ‚Ì”r…ˆ—jiƒŒƒrƒ…[˜_•¶j

2. •ŸŽmŒ[mCš ¼ÂC‰ª–ì–MGC‹{“c’¼KC”öú±•Û•vF ’¾…A•¨ƒzƒUƒLƒmƒtƒTƒ‚‚̐AÍ‹y‚ÑŠ ‚èŽæ‚肪“®A•¨ƒvƒ‰ƒ“ƒNƒgƒ““®‘Ô‚É‹y‚Ú‚·‰e‹¿C—p…‚Æ”p…, 52 (8), 631-639 (2010).

3. —Ñ‹I’jA‹{“c’¼KA”öè•Û•vFH“c‚̐…“c‚ÉŒ©‚ç‚ê‚郏ƒ€ƒV—ށCH“cŽ©‘RŽjŒ¤‹†CNo.57: 16-19 (2010).

4. Nakamoto, T., Okano, K., Kaul, C.S., Utsumi, M.FPhylogenetic Analysis of microcystin Biosynthesis Gene-mcyF from Microcystis. Japanese Journal of Water treatment Biology, 47(1): 29-36 (2011).i—•‘”“Ő¶¬ˆâ“`Žq‚ÌŒn“‰ðÍ)

5. Grangeon, S., Lanson, B., Miyata, N., Tani, Y., and Manceau, A.: Structure of nanocrystalline phyllomanganates produced by freshwater fungi. American Mineralogist, 95: 1608-1616 (2010).i^‹Û‚ªŒ`¬‚·‚éƒ}ƒ“ƒKƒ“Ž_‰»•¨‚̃iƒmŒ‹»\‘¢j

2009”N

1. ”öè•Û•vCˆ¢•”ŒOF—L—pA•¨‚ð—p‚¢‚½¶Šˆ”r…“™‚̍‚“xˆ—\ƒoƒCƒIƒWƒIƒtƒBƒ‹ƒ^[‚Ì“K—pCBIOINDUSTRY, 26 (11): 28-37 (2009).

2. ‚“c‡C‰Ž“cŠîC”öè•Û•vFŠ±‘ñ‚³‚ꂽ”ª˜YŠƒ‚̐…‘‚̈⑶“I¶ˆç’n‚ɂ‚¢‚āC…‘Œ¤‹†‰ïŽC92: 13-21 (2009).

3. Ohko, Y., Nagao, Y., Okano, K., Sugiura, N., Fukuda, A., Yang, Y., Negishi, N., Takeuchi, M., Hanad, S.: Prevention of Phormidium tenue biofilm formation by TiO2 photocatalysis. Microbes and Environments, 24(3): 241-245 (2009).iŽ_‰»ƒ`ƒ^ƒ“G”}‚É‚æ‚é—•‘”ƒoƒCƒIƒtƒBƒ‹ƒ€¶¬‚Ì—}§j

4. Okano, K., Shimizu, K., Kawauchi, Y., Maseda, H., Utsumi, M., Zhang, Z., Neilan, B. A., Sugiura, N.: Characteristics of a microcystin-degrading bacterium under alkaline environmental conditions. Journal of Toxicology,DOI 10.1155/2009/954291 (2009)i—•‘”“Å•ª‰ð×‹Û‚̉ðÍj